RepoMirrors
/
ffmpeg
mirror of https://git.ffmpeg.org/ffmpeg.git
1
0
Fork 0
Code Issues Projects Releases Wiki Activity

avfilter/af_sofalizer: switch to libmysofa 

Signed-off-by: Paul B Mahol <onemda@gmail.com>
This commit is contained in:
Paul B Mahol 2017-06-03 01:39:04 +02:00
parent a32a6b4201
commit 2336c76b22
4 changed files with 195 additions and 516 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

1
Changelog
View File

@ -17,6 +17,7 @@ version <next>:
- remove the libnut muxer/demuxer wrappers
- remove the libschroedinger encoder/decoder wrappers
- surround audio filter
- sofalizer filter switched to libmysofa
version 3.3:
- CrystalHD decoder moved to new decode API

8
configure vendored
View File

@ -277,7 +277,7 @@ External library support:
--disable-lzma disable lzma [autodetect]
--enable-decklink enable Blackmagic DeckLink I/O support [no]
--enable-mediacodec enable Android MediaCodec support [no]
--enable-netcdf enable NetCDF, needed for sofalizer filter [no]
--enable-libmysofa enable libmysofa, needed for sofalizer filter [no]
--enable-openal enable OpenAL 1.1 capture support [no]
--enable-opencl enable OpenCL code
--enable-opengl enable OpenGL rendering [no]
@ -1550,6 +1550,7 @@ EXTERNAL_LIBRARY_LIST="
libkvazaar
libmodplug
libmp3lame
libmysofa
libopencv
libopenh264
libopenjpeg
@ -1576,7 +1577,6 @@ EXTERNAL_LIBRARY_LIST="
libzmq
libzvbi
mediacodec
netcdf
openal
opencl
opengl
@ -3156,7 +3156,7 @@ showspectrumpic_filter_deps="avcodec"
showspectrumpic_filter_select="fft"
signature_filter_deps="gpl avcodec avformat"
smartblur_filter_deps="gpl swscale"
sofalizer_filter_deps="netcdf avcodec"
sofalizer_filter_deps="libmysofa avcodec"
sofalizer_filter_select="fft"
spectrumsynth_filter_deps="avcodec"
spectrumsynth_filter_select="fft"
@ -5822,6 +5822,7 @@ enabled libmfx && { use_pkg_config libmfx "mfx/mfxvideo.h" MFXInit ||
{ require libmfx "mfx/mfxvideo.h" MFXInit -llibmfx && warn "using libmfx without pkg-config"; } }
enabled libmodplug && require_pkg_config libmodplug libmodplug/modplug.h ModPlug_Load
enabled libmp3lame && require "libmp3lame >= 3.98.3" lame/lame.h lame_set_VBR_quality -lmp3lame
enabled libmysofa && require libmysofa "mysofa.h" mysofa_load -lmysofa
enabled libnpp && require libnpp npp.h nppGetLibVersion -lnppi -lnppc
enabled libopencore_amrnb && require libopencore_amrnb opencore-amrnb/interf_dec.h Decoder_Interface_init -lopencore-amrnb
enabled libopencore_amrwb && require libopencore_amrwb opencore-amrwb/dec_if.h D_IF_init -lopencore-amrwb
@ -5919,7 +5920,6 @@ enabled mmal && { check_lib mmal interface/mmal/mmal.h mmal_port_co
check_lib mmal interface/mmal/mmal.h mmal_port_connect -lmmal_core -lmmal_util -lmmal_vc_client -lbcm_host; } ||
die "ERROR: mmal not found" &&
check_func_headers interface/mmal/mmal.h "MMAL_PARAMETER_VIDEO_MAX_NUM_CALLBACKS"; }
enabled netcdf && require_pkg_config netcdf netcdf.h nc_inq_libvers
enabled openal && { { for al_extralibs in "${OPENAL_LIBS}" "-lopenal" "-lOpenAL32"; do
check_lib openal 'AL/al.h' alGetError "${al_extralibs}" && break; done } ||
die "ERROR: openal not found"; } &&

2
doc/filters.texi
View File

@ -3571,7 +3571,7 @@ SOFAlizer is developed at the Acoustics Research Institute (ARI) of the
Austrian Academy of Sciences.
To enable compilation of this filter you need to configure FFmpeg with
@code{--enable-netcdf}.
@code{--enable-libmysofa}.
The filter accepts the following options:

700
libavfilter/af_sofalizer.c
View File

@ -26,7 +26,7 @@
*****************************************************************************/
#include <math.h>
#include <netcdf.h>
#include <mysofa.h>
#include "libavcodec/avfft.h"
#include "libavutil/avstring.h"
@ -41,18 +41,12 @@
#define TIME_DOMAIN 0
#define FREQUENCY_DOMAIN 1
typedef struct NCSofa { /* contains data of one SOFA file */
int ncid; /* netCDF ID of the opened SOFA file */
typedef struct MySofa { /* contains data of one SOFA file */
struct MYSOFA_EASY *easy;
int n_samples; /* length of one impulse response (IR) */
int m_dim; /* number of measurement positions */
int *data_delay; /* broadband delay of each IR */
/* all measurement positions for each receiver (i.e. ear): */
float *sp_a; /* azimuth angles */
float *sp_e; /* elevation angles */
float *sp_r; /* radii */
/* data at each measurement position for each receiver: */
float *data_ir; /* IRs (time-domain) */
} NCSofa;
float *lir, *rir; /* IRs (time-domain) */
int max_delay;
} MySofa;
typedef struct VirtualSpeaker {
uint8_t set;
@ -64,7 +58,7 @@ typedef struct SOFAlizerContext {
const AVClass *class;
char *filename; /* name of SOFA file */
NCSofa sofa; /* contains data of the SOFA file */
MySofa sofa; /* contains data of the SOFA file */
int sample_rate; /* sample rate from SOFA file */
float *speaker_azim; /* azimuth of the virtual loudspeakers */
@ -107,271 +101,33 @@ typedef struct SOFAlizerContext {
AVFloatDSPContext *fdsp;
} SOFAlizerContext;
static int close_sofa(struct NCSofa *sofa)
static int close_sofa(struct MySofa *sofa)
{
av_freep(&sofa->data_delay);
av_freep(&sofa->sp_a);
av_freep(&sofa->sp_e);
av_freep(&sofa->sp_r);
av_freep(&sofa->data_ir);
nc_close(sofa->ncid);
sofa->ncid = 0;
mysofa_close(sofa->easy);
sofa->easy = NULL;
return 0;
}
static int load_sofa(AVFilterContext *ctx, char *filename, int *samplingrate)
static int preload_sofa(AVFilterContext *ctx, char *filename, int *samplingrate)
{
struct SOFAlizerContext *s = ctx->priv;
/* variables associated with content of SOFA file: */
int ncid, n_dims, n_vars, n_gatts, n_unlim_dim_id, status;
char data_delay_dim_name[NC_MAX_NAME];
float *sp_a, *sp_e, *sp_r, *data_ir;
char *sofa_conventions;
char dim_name[NC_MAX_NAME]; /* names of netCDF dimensions */
size_t *dim_length; /* lengths of netCDF dimensions */
char *text;
unsigned int sample_rate;
int data_delay_dim_id[2];
int samplingrate_id;
int data_delay_id;
int n_samples;
int m_dim_id = -1;
int n_dim_id = -1;
int data_ir_id;
size_t att_len;
int m_dim;
int *data_delay;
int sp_id;
int i, ret;
struct MYSOFA_HRTF *mysofa;
int ret;
s->sofa.ncid = 0;
status = nc_open(filename, NC_NOWRITE, &ncid); /* open SOFA file read-only */
if (status != NC_NOERR) {
mysofa = mysofa_load(filename, &ret);
if (ret || !mysofa) {
av_log(ctx, AV_LOG_ERROR, "Can't find SOFA-file '%s'\n", filename);
return AVERROR(EINVAL);
}
/* get number of dimensions, vars, global attributes and Id of unlimited dimensions: */
nc_inq(ncid, &n_dims, &n_vars, &n_gatts, &n_unlim_dim_id);
/* -- get number of measurements ("M") and length of one IR ("N") -- */
dim_length = av_malloc_array(n_dims, sizeof(*dim_length));
if (!dim_length) {
nc_close(ncid);
return AVERROR(ENOMEM);
}
for (i = 0; i < n_dims; i++) { /* go through all dimensions of file */
nc_inq_dim(ncid, i, (char *)&dim_name, &dim_length[i]); /* get dimensions */
if (!strncmp("M", (const char *)&dim_name, 1)) /* get ID of dimension "M" */
m_dim_id = i;
if (!strncmp("N", (const char *)&dim_name, 1)) /* get ID of dimension "N" */
n_dim_id = i;
}
if ((m_dim_id == -1) || (n_dim_id == -1)) { /* dimension "M" or "N" couldn't be found */
av_log(ctx, AV_LOG_ERROR, "Can't find required dimensions in SOFA file.\n");
av_freep(&dim_length);
nc_close(ncid);
if (mysofa->DataSamplingRate.elements != 1)
return AVERROR(EINVAL);
}
n_samples = dim_length[n_dim_id]; /* get length of one IR */
m_dim = dim_length[m_dim_id]; /* get number of measurements */
av_freep(&dim_length);
/* -- check file type -- */
/* get length of attritube "Conventions" */
status = nc_inq_attlen(ncid, NC_GLOBAL, "Conventions", &att_len);
if (status != NC_NOERR) {
av_log(ctx, AV_LOG_ERROR, "Can't get length of attribute \"Conventions\".\n");
nc_close(ncid);
return AVERROR_INVALIDDATA;
}
/* check whether file is SOFA file */
text = av_malloc(att_len + 1);
if (!text) {
nc_close(ncid);
return AVERROR(ENOMEM);
}
nc_get_att_text(ncid, NC_GLOBAL, "Conventions", text);
*(text + att_len) = 0;
if (strncmp("SOFA", text, 4)) {
av_log(ctx, AV_LOG_ERROR, "Not a SOFA file!\n");
av_freep(&text);
nc_close(ncid);
return AVERROR(EINVAL);
}
av_freep(&text);
status = nc_inq_attlen(ncid, NC_GLOBAL, "License", &att_len);
if (status == NC_NOERR) {
text = av_malloc(att_len + 1);
if (text) {
nc_get_att_text(ncid, NC_GLOBAL, "License", text);
*(text + att_len) = 0;
av_log(ctx, AV_LOG_INFO, "SOFA file License: %s\n", text);
av_freep(&text);
}
}
status = nc_inq_attlen(ncid, NC_GLOBAL, "SourceDescription", &att_len);
if (status == NC_NOERR) {
text = av_malloc(att_len + 1);
if (text) {
nc_get_att_text(ncid, NC_GLOBAL, "SourceDescription", text);
*(text + att_len) = 0;
av_log(ctx, AV_LOG_INFO, "SOFA file SourceDescription: %s\n", text);
av_freep(&text);
}
}
status = nc_inq_attlen(ncid, NC_GLOBAL, "Comment", &att_len);
if (status == NC_NOERR) {
text = av_malloc(att_len + 1);
if (text) {
nc_get_att_text(ncid, NC_GLOBAL, "Comment", text);
*(text + att_len) = 0;
av_log(ctx, AV_LOG_INFO, "SOFA file Comment: %s\n", text);
av_freep(&text);
}
}
status = nc_inq_attlen(ncid, NC_GLOBAL, "SOFAConventions", &att_len);
if (status != NC_NOERR) {
av_log(ctx, AV_LOG_ERROR, "Can't get length of attribute \"SOFAConventions\".\n");
nc_close(ncid);
return AVERROR_INVALIDDATA;
}
sofa_conventions = av_malloc(att_len + 1);
if (!sofa_conventions) {
nc_close(ncid);
return AVERROR(ENOMEM);
}
nc_get_att_text(ncid, NC_GLOBAL, "SOFAConventions", sofa_conventions);
*(sofa_conventions + att_len) = 0;
if (strncmp("SimpleFreeFieldHRIR", sofa_conventions, att_len)) {
av_log(ctx, AV_LOG_ERROR, "Not a SimpleFreeFieldHRIR file!\n");
av_freep(&sofa_conventions);
nc_close(ncid);
return AVERROR(EINVAL);
}
av_freep(&sofa_conventions);
/* -- get sampling rate of HRTFs -- */
/* read ID, then value */
status = nc_inq_varid(ncid, "Data.SamplingRate", &samplingrate_id);
status += nc_get_var_uint(ncid, samplingrate_id, &sample_rate);
if (status != NC_NOERR) {
av_log(ctx, AV_LOG_ERROR, "Couldn't read Data.SamplingRate.\n");
nc_close(ncid);
return AVERROR(EINVAL);
}
*samplingrate = sample_rate; /* remember sampling rate */
/* -- allocate memory for one value for each measurement position: -- */
sp_a = s->sofa.sp_a = av_malloc_array(m_dim, sizeof(float));
sp_e = s->sofa.sp_e = av_malloc_array(m_dim, sizeof(float));
sp_r = s->sofa.sp_r = av_malloc_array(m_dim, sizeof(float));
/* delay and IR values required for each ear and measurement position: */
data_delay = s->sofa.data_delay = av_calloc(m_dim, 2 * sizeof(int));
data_ir = s->sofa.data_ir = av_calloc(m_dim * FFALIGN(n_samples, 16), sizeof(float) * 2);
if (!data_delay || !sp_a || !sp_e || !sp_r || !data_ir) {
/* if memory could not be allocated */
close_sofa(&s->sofa);
return AVERROR(ENOMEM);
}
/* get impulse responses (HRTFs): */
/* get corresponding ID */
status = nc_inq_varid(ncid, "Data.IR", &data_ir_id);
status += nc_get_var_float(ncid, data_ir_id, data_ir); /* read and store IRs */
if (status != NC_NOERR) {
av_log(ctx, AV_LOG_ERROR, "Couldn't read Data.IR!\n");
ret = AVERROR(EINVAL);
goto error;
}
/* get source positions of the HRTFs in the SOFA file: */
status = nc_inq_varid(ncid, "SourcePosition", &sp_id); /* get corresponding ID */
status += nc_get_vara_float(ncid, sp_id, (size_t[2]){ 0, 0 } ,
(size_t[2]){ m_dim, 1}, sp_a); /* read & store azimuth angles */
status += nc_get_vara_float(ncid, sp_id, (size_t[2]){ 0, 1 } ,
(size_t[2]){ m_dim, 1}, sp_e); /* read & store elevation angles */
status += nc_get_vara_float(ncid, sp_id, (size_t[2]){ 0, 2 } ,
(size_t[2]){ m_dim, 1}, sp_r); /* read & store radii */
if (status != NC_NOERR) { /* if any source position variable coudn't be read */
av_log(ctx, AV_LOG_ERROR, "Couldn't read SourcePosition.\n");
ret = AVERROR(EINVAL);
goto error;
}
/* read Data.Delay, check for errors and fit it to data_delay */
status = nc_inq_varid(ncid, "Data.Delay", &data_delay_id);
status += nc_inq_vardimid(ncid, data_delay_id, &data_delay_dim_id[0]);
status += nc_inq_dimname(ncid, data_delay_dim_id[0], data_delay_dim_name);
if (status != NC_NOERR) {
av_log(ctx, AV_LOG_ERROR, "Couldn't read Data.Delay.\n");
ret = AVERROR(EINVAL);
goto error;
}
/* Data.Delay dimension check */
/* dimension of Data.Delay is [I R]: */
if (!strncmp(data_delay_dim_name, "I", 2)) {
/* check 2 characters to assure string is 0-terminated after "I" */
int delay[2]; /* delays get from SOFA file: */
int *data_delay_r;
av_log(ctx, AV_LOG_DEBUG, "Data.Delay has dimension [I R]\n");
status = nc_get_var_int(ncid, data_delay_id, &delay[0]);
if (status != NC_NOERR) {
av_log(ctx, AV_LOG_ERROR, "Couldn't read Data.Delay\n");
ret = AVERROR(EINVAL);
goto error;
}
data_delay_r = data_delay + m_dim;
for (i = 0; i < m_dim; i++) { /* extend given dimension [I R] to [M R] */
/* assign constant delay value for all measurements to data_delay fields */
data_delay[i] = delay[0];
data_delay_r[i] = delay[1];
}
/* dimension of Data.Delay is [M R] */
} else if (!strncmp(data_delay_dim_name, "M", 2)) {
av_log(ctx, AV_LOG_ERROR, "Data.Delay in dimension [M R]\n");
/* get delays from SOFA file: */
status = nc_get_var_int(ncid, data_delay_id, data_delay);
if (status != NC_NOERR) {
av_log(ctx, AV_LOG_ERROR, "Couldn't read Data.Delay\n");
ret = AVERROR(EINVAL);
goto error;
}
} else { /* dimension of Data.Delay is neither [I R] nor [M R] */
av_log(ctx, AV_LOG_ERROR, "Data.Delay does not have the required dimensions [I R] or [M R].\n");
ret = AVERROR(EINVAL);
goto error;
}
/* save information in SOFA struct: */
s->sofa.m_dim = m_dim; /* no. measurement positions */
s->sofa.n_samples = n_samples; /* length on one IR */
s->sofa.ncid = ncid; /* netCDF ID of SOFA file */
nc_close(ncid); /* close SOFA file */
av_log(ctx, AV_LOG_DEBUG, "m_dim: %d n_samples %d\n", m_dim, n_samples);
*samplingrate = mysofa->DataSamplingRate.values[0];
s->sofa.n_samples = mysofa->N;
mysofa_free(mysofa);
return 0;
error:
close_sofa(&s->sofa);
return ret;
}
static int parse_channel_name(char **arg, int *rchannel, char *buf)
@ -507,83 +263,6 @@ static int get_speaker_pos(AVFilterContext *ctx,
}
static int max_delay(struct NCSofa *sofa)
{
int i, max = 0;
for (i = 0; i < sofa->m_dim * 2; i++) {
/* search maximum delay in given SOFA file */
max = FFMAX(max, sofa->data_delay[i]);
}
return max;
}
static int find_m(SOFAlizerContext *s, int azim, int elev, float radius)
{
/* get source positions and M of currently selected SOFA file */
float *sp_a = s->sofa.sp_a; /* azimuth angle */
float *sp_e = s->sofa.sp_e; /* elevation angle */
float *sp_r = s->sofa.sp_r; /* radius */
int m_dim = s->sofa.m_dim; /* no. measurements */
int best_id = 0; /* index m currently closest to desired source pos. */
float delta = 1000; /* offset between desired and currently best pos. */
float current;
int i;
for (i = 0; i < m_dim; i++) {
/* search through all measurements in currently selected SOFA file */
/* distance of current to desired source position: */
current = fabs(sp_a[i] - azim) +
fabs(sp_e[i] - elev) +
fabs(sp_r[i] - radius);
if (current <= delta) {
/* if current distance is smaller than smallest distance so far */
delta = current;
best_id = i; /* remember index */
}
}
return best_id;
}
static int compensate_volume(AVFilterContext *ctx)
{
struct SOFAlizerContext *s = ctx->priv;
float compensate;
float energy = 0;
float *ir;
int m;
if (s->sofa.ncid) {
/* find IR at front center position in the SOFA file (IR closest to 0°,0°,1m) */
struct NCSofa *sofa = &s->sofa;
m = find_m(s, 0, 0, 1);
/* get energy of that IR and compensate volume */
ir = sofa->data_ir + 2 * m * sofa->n_samples;
if (sofa->n_samples & 31) {
energy = avpriv_scalarproduct_float_c(ir, ir, sofa->n_samples);
} else {
energy = s->fdsp->scalarproduct_float(ir, ir, sofa->n_samples);
}
compensate = 256 / (sofa->n_samples * sqrt(energy));
av_log(ctx, AV_LOG_DEBUG, "Compensate-factor: %f\n", compensate);
ir = sofa->data_ir;
/* apply volume compensation to IRs */
if (sofa->n_samples & 31) {
int i;
for (i = 0; i < sofa->n_samples * sofa->m_dim * 2; i++) {
ir[i] = ir[i] * compensate;
}
} else {
s->fdsp->vector_fmul_scalar(ir, ir, compensate, sofa->n_samples * sofa->m_dim * 2);
emms_c();
}
}
return 0;
}
typedef struct ThreadData {
AVFrame *in, *out;
int *write;
@ -629,10 +308,10 @@ static int sofalizer_convolute(AVFilterContext *ctx, void *arg, int jobnr, int n
for (i = 0; i < in->nb_samples; i++) {
const float *temp_ir = ir; /* using same set of IRs for each sample */
*dst = 0;
dst[0] = 0;
for (l = 0; l < in_channels; l++) {
/* write current input sample to ringbuffer (for each channel) */
*(buffer[l] + wr) = src[l];
buffer[l][wr] = src[l];
}
/* loop goes through all channels to be convolved */
@ -643,31 +322,31 @@ static int sofalizer_convolute(AVFilterContext *ctx, void *arg, int jobnr, int n
/* LFE is an input channel but requires no convolution */
/* apply gain to LFE signal and add to output buffer */
*dst += *(buffer[s->lfe_channel] + wr) * s->gain_lfe;
temp_ir += FFALIGN(n_samples, 16);
temp_ir += FFALIGN(n_samples, 32);
continue;
}
/* current read position in ringbuffer: input sample write position
* - delay for l-th ch. + diff. betw. IR length and buffer length
* (mod buffer length) */
read = (wr - *(delay + l) - (n_samples - 1) + buffer_length) & modulo;
read = (wr - delay[l] - (n_samples - 1) + buffer_length) & modulo;
if (read + n_samples < buffer_length) {
memcpy(temp_src, bptr + read, n_samples * sizeof(*temp_src));
memmove(temp_src, bptr + read, n_samples * sizeof(*temp_src));
} else {
int len = FFMIN(n_samples - (read % n_samples), buffer_length - read);
memcpy(temp_src, bptr + read, len * sizeof(*temp_src));
memcpy(temp_src + len, bptr, (n_samples - len) * sizeof(*temp_src));
memmove(temp_src, bptr + read, len * sizeof(*temp_src));
memmove(temp_src + len, bptr, (n_samples - len) * sizeof(*temp_src));
}
/* multiply signal and IR, and add up the results */
dst[0] += s->fdsp->scalarproduct_float(temp_ir, temp_src, n_samples);
temp_ir += FFALIGN(n_samples, 16);
temp_ir += FFALIGN(n_samples, 32);
}
/* clippings counter */
if (fabs(*dst) > 1)
if (fabs(dst[0]) > 1)
*n_clippings += 1;
/* move output buffer pointer by +2 to get to next sample of processed channel: */
@ -875,14 +554,14 @@ static int query_formats(AVFilterContext *ctx)
return ff_set_common_samplerates(ctx, formats);
}
static int load_data(AVFilterContext *ctx, int azim, int elev, float radius)
static int load_data(AVFilterContext *ctx, int azim, int elev, float radius, int sample_rate)
{
struct SOFAlizerContext *s = ctx->priv;
const int n_samples = s->sofa.n_samples;
int n_samples;
int n_conv = s->n_conv; /* no. channels to convolve */
int n_fft = s->n_fft;
int delay_l[16]; /* broadband delay for each IR */
int delay_r[16];
int n_fft;
float delay_l; /* broadband delay for each IR */
float delay_r;
int nb_input_channels = ctx->inputs[0]->channels; /* no. input channels */
float gain_lin = expf((s->gain - 3 * nb_input_channels) / 20 * M_LN10); /* gain - 3dB/channel */
FFTComplex *data_hrtf_l = NULL;
@ -892,68 +571,166 @@ static int load_data(AVFilterContext *ctx, int azim, int elev, float radius)
float *data_ir_l = NULL;
float *data_ir_r = NULL;
int offset = 0; /* used for faster pointer arithmetics in for-loop */
int m[16]; /* measurement index m of IR closest to required source positions */
int i, j, azim_orig = azim, elev_orig = elev;
int filter_length, ret = 0;
int n_current;
int n_max = 0;
if (!s->sofa.ncid) { /* if an invalid SOFA file has been selected */
s->sofa.easy = mysofa_open(s->filename, sample_rate, &filter_length, &ret);
if (!s->sofa.easy || ret) { /* if an invalid SOFA file has been selected */
av_log(ctx, AV_LOG_ERROR, "Selected SOFA file is invalid. Please select valid SOFA file.\n");
return AVERROR_INVALIDDATA;
}
if (s->type == TIME_DOMAIN) {
s->temp_src[0] = av_calloc(FFALIGN(n_samples, 16), sizeof(float));
s->temp_src[1] = av_calloc(FFALIGN(n_samples, 16), sizeof(float));
n_samples = s->sofa.n_samples;
/* get temporary IR for L and R channel */
data_ir_l = av_calloc(n_conv * FFALIGN(n_samples, 16), sizeof(*data_ir_l));
data_ir_r = av_calloc(n_conv * FFALIGN(n_samples, 16), sizeof(*data_ir_r));
if (!data_ir_r || !data_ir_l || !s->temp_src[0] || !s->temp_src[1]) {
av_free(data_ir_l);
av_free(data_ir_r);
return AVERROR(ENOMEM);
s->data_ir[0] = av_calloc(FFALIGN(n_samples, 32), sizeof(float) * s->n_conv);
s->data_ir[1] = av_calloc(FFALIGN(n_samples, 32), sizeof(float) * s->n_conv);
s->delay[0] = av_calloc(s->n_conv, sizeof(int));
s->delay[1] = av_calloc(s->n_conv, sizeof(int));
if (!s->data_ir[0] || !s->data_ir[1] || !s->delay[0] || !s->delay[1]) {
ret = AVERROR(ENOMEM);
goto fail;
}
/* get temporary IR for L and R channel */
data_ir_l = av_calloc(n_conv * FFALIGN(n_samples, 32), sizeof(*data_ir_l));
data_ir_r = av_calloc(n_conv * FFALIGN(n_samples, 32), sizeof(*data_ir_r));
if (!data_ir_r || !data_ir_l) {
ret = AVERROR(ENOMEM);
goto fail;
}
if (s->type == TIME_DOMAIN) {
s->temp_src[0] = av_calloc(FFALIGN(n_samples, 32), sizeof(float));
s->temp_src[1] = av_calloc(FFALIGN(n_samples, 32), sizeof(float));
if (!s->temp_src[0] || !s->temp_src[1]) {
ret = AVERROR(ENOMEM);
goto fail;
}
}
s->speaker_azim = av_calloc(s->n_conv, sizeof(*s->speaker_azim));
s->speaker_elev = av_calloc(s->n_conv, sizeof(*s->speaker_elev));
if (!s->speaker_azim || !s->speaker_elev) {
ret = AVERROR(ENOMEM);
goto fail;
}
/* get speaker positions */
if ((ret = get_speaker_pos(ctx, s->speaker_azim, s->speaker_elev)) < 0) {
av_log(ctx, AV_LOG_ERROR, "Couldn't get speaker positions. Input channel configuration not supported.\n");
goto fail;
}
for (i = 0; i < s->n_conv; i++) {
float coordinates[3];
/* load and store IRs and corresponding delays */
azim = (int)(s->speaker_azim[i] + azim_orig) % 360;
elev = (int)(s->speaker_elev[i] + elev_orig) % 90;
coordinates[0] = azim;
coordinates[1] = elev;
coordinates[2] = radius;
mysofa_s2c(coordinates);
/* get id of IR closest to desired position */
mysofa_getfilter_float(s->sofa.easy, coordinates[0], coordinates[1], coordinates[2],
data_ir_l + FFALIGN(n_samples, 32) * i,
data_ir_r + FFALIGN(n_samples, 32) * i,
&delay_l, &delay_r);
s->delay[0][i] = delay_l * sample_rate;
s->delay[1][i] = delay_r * sample_rate;
s->sofa.max_delay = FFMAX3(s->sofa.max_delay, s->delay[0][i], s->delay[1][i]);
}
/* get size of ringbuffer (longest IR plus max. delay) */
/* then choose next power of 2 for performance optimization */
n_current = s->sofa.n_samples + s->sofa.max_delay;
/* length of longest IR plus max. delay */
n_max = FFMAX(n_max, n_current);
/* buffer length is longest IR plus max. delay -> next power of 2
(32 - count leading zeros gives required exponent) */
s->buffer_length = 1 << (32 - ff_clz(n_max));
s->n_fft = n_fft = 1 << (32 - ff_clz(n_max + sample_rate));
if (s->type == FREQUENCY_DOMAIN) {
av_fft_end(s->fft[0]);
av_fft_end(s->fft[1]);
s->fft[0] = av_fft_init(log2(s->n_fft), 0);
s->fft[1] = av_fft_init(log2(s->n_fft), 0);
av_fft_end(s->ifft[0]);
av_fft_end(s->ifft[1]);
s->ifft[0] = av_fft_init(log2(s->n_fft), 1);
s->ifft[1] = av_fft_init(log2(s->n_fft), 1);
if (!s->fft[0] || !s->fft[1] || !s->ifft[0] || !s->ifft[1]) {
av_log(ctx, AV_LOG_ERROR, "Unable to create FFT contexts of size %d.\n", s->n_fft);
ret = AVERROR(ENOMEM);
goto fail;
}
}
if (s->type == TIME_DOMAIN) {
s->ringbuffer[0] = av_calloc(s->buffer_length, sizeof(float) * nb_input_channels);
s->ringbuffer[1] = av_calloc(s->buffer_length, sizeof(float) * nb_input_channels);
} else {
/* get temporary HRTF memory for L and R channel */
data_hrtf_l = av_malloc_array(n_fft, sizeof(*data_hrtf_l) * n_conv);
data_hrtf_r = av_malloc_array(n_fft, sizeof(*data_hrtf_r) * n_conv);
if (!data_hrtf_r || !data_hrtf_l) {
av_free(data_hrtf_l);
av_free(data_hrtf_r);
return AVERROR(ENOMEM);
ret = AVERROR(ENOMEM);
goto fail;
}
s->ringbuffer[0] = av_calloc(s->buffer_length, sizeof(float));
s->ringbuffer[1] = av_calloc(s->buffer_length, sizeof(float));
s->temp_fft[0] = av_malloc_array(s->n_fft, sizeof(FFTComplex));
s->temp_fft[1] = av_malloc_array(s->n_fft, sizeof(FFTComplex));
if (!s->temp_fft[0] || !s->temp_fft[1]) {
ret = AVERROR(ENOMEM);
goto fail;
}
}
if (!s->ringbuffer[0] || !s->ringbuffer[1]) {
ret = AVERROR(ENOMEM);
goto fail;
}
if (s->type == FREQUENCY_DOMAIN) {
fft_in_l = av_calloc(n_fft, sizeof(*fft_in_l));
fft_in_r = av_calloc(n_fft, sizeof(*fft_in_r));
if (!fft_in_l || !fft_in_r) {
ret = AVERROR(ENOMEM);
goto fail;
}
}
for (i = 0; i < s->n_conv; i++) {
/* load and store IRs and corresponding delays */
azim = (int)(s->speaker_azim[i] + azim_orig) % 360;
elev = (int)(s->speaker_elev[i] + elev_orig) % 90;
/* get id of IR closest to desired position */
m[i] = find_m(s, azim, elev, radius);
float *lir, *rir;
/* load the delays associated with the current IRs */
delay_l[i] = *(s->sofa.data_delay + 2 * m[i]);
delay_r[i] = *(s->sofa.data_delay + 2 * m[i] + 1);
offset = i * FFALIGN(n_samples, 32); /* no. samples already written */
lir = data_ir_l + offset;
rir = data_ir_r + offset;
if (s->type == TIME_DOMAIN) {
offset = i * FFALIGN(n_samples, 16); /* no. samples already written */
for (j = 0; j < n_samples; j++) {
/* load reversed IRs of the specified source position
* sample-by-sample for left and right ear; and apply gain */
*(data_ir_l + offset + j) = /* left channel */
*(s->sofa.data_ir + 2 * m[i] * n_samples + n_samples - 1 - j) * gain_lin;
*(data_ir_r + offset + j) = /* right channel */
*(s->sofa.data_ir + 2 * m[i] * n_samples + n_samples - 1 - j + n_samples) * gain_lin;
s->data_ir[0][offset + j] = lir[n_samples - 1 - j] * gain_lin;
s->data_ir[1][offset + j] = rir[n_samples - 1 - j] * gain_lin;
}
} else {
fft_in_l = av_calloc(n_fft, sizeof(*fft_in_l));
fft_in_r = av_calloc(n_fft, sizeof(*fft_in_r));
if (!fft_in_l || !fft_in_r) {
av_free(data_hrtf_l);
av_free(data_hrtf_r);
av_free(fft_in_l);
av_free(fft_in_r);
return AVERROR(ENOMEM);
}
memset(fft_in_l, 0, n_fft * sizeof(*fft_in_l));
memset(fft_in_r, 0, n_fft * sizeof(*fft_in_r));
offset = i * n_fft; /* no. samples already written */
for (j = 0; j < n_samples; j++) {
@ -961,10 +738,8 @@ static int load_data(AVFilterContext *ctx, int azim, int elev, float radius)
* sample-by-sample and apply gain,
* L channel is loaded to real part, R channel to imag part,
* IRs ared shifted by L and R delay */
fft_in_l[delay_l[i] + j].re = /* left channel */
*(s->sofa.data_ir + 2 * m[i] * n_samples + j) * gain_lin;
fft_in_r[delay_r[i] + j].re = /* right channel */
*(s->sofa.data_ir + (2 * m[i] + 1) * n_samples + j) * gain_lin;
fft_in_l[s->delay[0][i] + j].re = lir[j] * gain_lin;
fft_in_r[s->delay[1][i] + j].re = rir[j] * gain_lin;
}
/* actually transform to frequency domain (IRs -> HRTFs) */
@ -975,45 +750,33 @@ static int load_data(AVFilterContext *ctx, int azim, int elev, float radius)
av_fft_calc(s->fft[0], fft_in_r);
memcpy(data_hrtf_r + offset, fft_in_r, n_fft * sizeof(*fft_in_r));
}
av_log(ctx, AV_LOG_DEBUG, "Index: %d, Azimuth: %f, Elevation: %f, Radius: %f of SOFA file.\n",
m[i], *(s->sofa.sp_a + m[i]), *(s->sofa.sp_e + m[i]), *(s->sofa.sp_r + m[i]));
}
if (s->type == TIME_DOMAIN) {
/* copy IRs and delays to allocated memory in the SOFAlizerContext struct: */
memcpy(s->data_ir[0], data_ir_l, sizeof(float) * n_conv * FFALIGN(n_samples, 16));
memcpy(s->data_ir[1], data_ir_r, sizeof(float) * n_conv * FFALIGN(n_samples, 16));
av_freep(&data_ir_l); /* free temporary IR memory */
av_freep(&data_ir_r);
} else {
if (s->type == FREQUENCY_DOMAIN) {
s->data_hrtf[0] = av_malloc_array(n_fft * s->n_conv, sizeof(FFTComplex));
s->data_hrtf[1] = av_malloc_array(n_fft * s->n_conv, sizeof(FFTComplex));
if (!s->data_hrtf[0] || !s->data_hrtf[1]) {
av_freep(&data_hrtf_l);
av_freep(&data_hrtf_r);
av_freep(&fft_in_l);
av_freep(&fft_in_r);
return AVERROR(ENOMEM); /* memory allocation failed */
ret = AVERROR(ENOMEM);
goto fail;
}
memcpy(s->data_hrtf[0], data_hrtf_l, /* copy HRTF data to */
sizeof(FFTComplex) * n_conv * n_fft); /* filter struct */
memcpy(s->data_hrtf[1], data_hrtf_r,
sizeof(FFTComplex) * n_conv * n_fft);
av_freep(&data_hrtf_l); /* free temporary HRTF memory */
av_freep(&data_hrtf_r);
av_freep(&fft_in_l); /* free temporary FFT memory */
av_freep(&fft_in_r);
}
memcpy(s->delay[0], &delay_l[0], sizeof(int) * s->n_conv);
memcpy(s->delay[1], &delay_r[0], sizeof(int) * s->n_conv);
fail:
av_freep(&data_hrtf_l); /* free temporary HRTF memory */
av_freep(&data_hrtf_r);
return 0;
av_freep(&data_ir_l); /* free temprary IR memory */
av_freep(&data_ir_r);
av_freep(&fft_in_l); /* free temporary FFT memory */
av_freep(&fft_in_r);
return ret;
}
static av_cold int init(AVFilterContext *ctx)
@ -1026,12 +789,8 @@ static av_cold int init(AVFilterContext *ctx)
return AVERROR(EINVAL);
}
/* load SOFA file, */
/* initialize file IDs to 0 before attempting to load SOFA files,
* this assures that in case of error, only the memory of already
* loaded files is free'd */
s->sofa.ncid = 0;
ret = load_sofa(ctx, s->filename, &s->sample_rate);
/* preload SOFA file, */
ret = preload_sofa(ctx, s->filename, &s->sample_rate);
if (ret) {
/* file loading error */
av_log(ctx, AV_LOG_ERROR, "Error while loading SOFA file: '%s'\n", s->filename);
@ -1055,10 +814,6 @@ static int config_input(AVFilterLink *inlink)
{
AVFilterContext *ctx = inlink->dst;
SOFAlizerContext *s = ctx->priv;
int nb_input_channels = inlink->channels; /* no. input channels */
int n_max_ir = 0;
int n_current;
int n_max = 0;
int ret;
if (s->type == FREQUENCY_DOMAIN) {
@ -1070,85 +825,14 @@ static int config_input(AVFilterLink *inlink)
/* gain -3 dB per channel, -6 dB to get LFE on a similar level */
s->gain_lfe = expf((s->gain - 3 * inlink->channels - 6 + s->lfe_gain) / 20 * M_LN10);
s->n_conv = nb_input_channels;
/* get size of ringbuffer (longest IR plus max. delay) */
/* then choose next power of 2 for performance optimization */
n_current = s->sofa.n_samples + max_delay(&s->sofa);
if (n_current > n_max) {
/* length of longest IR plus max. delay (in all SOFA files) */
n_max = n_current;
/* length of longest IR (without delay, in all SOFA files) */
n_max_ir = s->sofa.n_samples;
}
/* buffer length is longest IR plus max. delay -> next power of 2
(32 - count leading zeros gives required exponent) */
s->buffer_length = 1 << (32 - ff_clz(n_max));
s->n_fft = 1 << (32 - ff_clz(n_max + inlink->sample_rate));
if (s->type == FREQUENCY_DOMAIN) {
av_fft_end(s->fft[0]);
av_fft_end(s->fft[1]);
s->fft[0] = av_fft_init(log2(s->n_fft), 0);
s->fft[1] = av_fft_init(log2(s->n_fft), 0);
av_fft_end(s->ifft[0]);
av_fft_end(s->ifft[1]);
s->ifft[0] = av_fft_init(log2(s->n_fft), 1);
s->ifft[1] = av_fft_init(log2(s->n_fft), 1);
if (!s->fft[0] || !s->fft[1] || !s->ifft[0] || !s->ifft[1]) {
av_log(ctx, AV_LOG_ERROR, "Unable to create FFT contexts of size %d.\n", s->n_fft);
return AVERROR(ENOMEM);
}
}
/* Allocate memory for the impulse responses, delays and the ringbuffers */
/* size: (longest IR) * (number of channels to convolute) */
s->data_ir[0] = av_calloc(FFALIGN(n_max_ir, 16), sizeof(float) * s->n_conv);
s->data_ir[1] = av_calloc(FFALIGN(n_max_ir, 16), sizeof(float) * s->n_conv);
/* length: number of channels to convolute */
s->delay[0] = av_malloc_array(s->n_conv, sizeof(float));
s->delay[1] = av_malloc_array(s->n_conv, sizeof(float));
/* length: (buffer length) * (number of input channels),
* OR: buffer length (if frequency domain processing)
* calloc zero-initializes the buffer */
if (s->type == TIME_DOMAIN) {
s->ringbuffer[0] = av_calloc(s->buffer_length, sizeof(float) * nb_input_channels);
s->ringbuffer[1] = av_calloc(s->buffer_length, sizeof(float) * nb_input_channels);
} else {
s->ringbuffer[0] = av_calloc(s->buffer_length, sizeof(float));
s->ringbuffer[1] = av_calloc(s->buffer_length, sizeof(float));
s->temp_fft[0] = av_malloc_array(s->n_fft, sizeof(FFTComplex));
s->temp_fft[1] = av_malloc_array(s->n_fft, sizeof(FFTComplex));
if (!s->temp_fft[0] || !s->temp_fft[1])
return AVERROR(ENOMEM);
}
/* length: number of channels to convolute */
s->speaker_azim = av_calloc(s->n_conv, sizeof(*s->speaker_azim));
s->speaker_elev = av_calloc(s->n_conv, sizeof(*s->speaker_elev));
/* memory allocation failed: */
if (!s->data_ir[0] || !s->data_ir[1] || !s->delay[1] ||
!s->delay[0] || !s->ringbuffer[0] || !s->ringbuffer[1] ||
!s->speaker_azim || !s->speaker_elev)
return AVERROR(ENOMEM);
compensate_volume(ctx);
/* get speaker positions */
if ((ret = get_speaker_pos(ctx, s->speaker_azim, s->speaker_elev)) < 0) {
av_log(ctx, AV_LOG_ERROR, "Couldn't get speaker positions. Input channel configuration not supported.\n");
return ret;
}
s->n_conv = inlink->channels;
/* load IRs to data_ir[0] and data_ir[1] for required directions */
if ((ret = load_data(ctx, s->rotation, s->elevation, s->radius)) < 0)
if ((ret = load_data(ctx, s->rotation, s->elevation, s->radius, inlink->sample_rate)) < 0)
return ret;
av_log(ctx, AV_LOG_DEBUG, "Samplerate: %d Channels to convolute: %d, Length of ringbuffer: %d x %d\n",
inlink->sample_rate, s->n_conv, nb_input_channels, s->buffer_length);
inlink->sample_rate, s->n_conv, inlink->channels, s->buffer_length);
return 0;
}
@ -1157,13 +841,7 @@ static av_cold void uninit(AVFilterContext *ctx)
{
SOFAlizerContext *s = ctx->priv;
if (s->sofa.ncid) {
av_freep(&s->sofa.sp_a);
av_freep(&s->sofa.sp_e);
av_freep(&s->sofa.sp_r);
av_freep(&s->sofa.data_delay);
av_freep(&s->sofa.data_ir);
}
close_sofa(&s->sofa);
av_fft_end(s->ifft[0]);
av_fft_end(s->ifft[1]);
av_fft_end(s->fft[0]);